To prevent uneven gloss on a printed image in a printing apparatus in which light-curable ink is used, a printing apparatus is provided. The printing apparatus includes a controller controls medium-conveying parts for conveying a medium so that the medium supplied from an upstream side is released on a downstream side; nozzles for discharging ink droplets cured by light irradiation onto the medium; a light-irradiation part for irradiating the medium with light; and medium-deforming parts arranged on the downstream side of the nozzles, holding the medium from the front and back, and deforming the medium so that an irregular shape is formed in cross section; the medium is conveyed downstream by the medium-conveying parts after the medium is deformed by the medium-deforming parts; droplets of ink are discharged from the nozzles to form an image on the surface of the medium; and the ink droplets discharged onto the medium are irradiated with light by the light-irradiation part to cure the droplets.
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5. A printing method for printing a medium by using a printing apparatus, the printing method comprising:
conveying the medium in a conveying direction;
forming an image composed of minute dots on the medium by discharging light-curable ink as droplets from nozzles, depositing the light-curable ink on the medium, and irradiating and curing the droplets deposited on the medium with light; and
deforming the medium by a medium-deforming part being arranged upstream relative to the nozzles in the conveying direction so that an irregular shape is formed in cross section before the forming of the image on the medium,
the printing apparatus including the nozzles and the medium-deforming part,
the medium-deforming part including a first roller and a second roller facing the first roller in a first direction, the first roller having at least one projecting part projecting outward from an outer circumference of the first roller and extending along a second direction perpendicular to the first direction and the conveying direction, the at least one projecting part extending straight along the second direction,
the deforming of the medium including holding the medium between the first roller and the second roller and pressing the at least one projecting part against the medium.
1. A printing apparatus for depositing ink droplets on a surface of a medium to form an image, the printing apparatus comprising:
a medium-conveying part; nozzles; a light-irradiation part; a medium-deforming part; and a controller configured to control the parts,
the medium-conveying part being configured to convey the medium so that the medium supplied from an upstream side is released on a downstream side,
the nozzles being configured to discharge ink droplets curable by light irradiation onto the medium,
the light-irradiation part being configured to irradiate the medium with light,
the medium-deforming part being arranged on the upstream side of the nozzles, and being configured to hold the medium from the front and back and deform the medium so that an irregular shape is formed in cross section, the medium-deforming part being configured from rollers for holding the medium while being orthogonal to the conveying direction of the medium, and irregularities being formed on the surface of one of the rollers,
the controller being configured to perform a medium-deforming step, an image-forming step, and a light-irradiating step,
in the medium-deforming step, the medium being conveyed downstream by the medium-conveying part after the medium is deformed by the medium-deforming part,
in the image-forming step, the ink droplets being discharged by the nozzles to form an image on the surface of the medium, and
in the light-irradiating step, the ink droplets discharged onto the medium being irradiated with light by the light-irradiation part to cure the droplets,
the surface of the medium on which the ink droplets are deposited being the front surface, the roller provided with irregularities being arranged facing the rear surface of the medium, and the roller provided with an elastic surface and formed from a material lacking any irregularities being arranged facing the front surface.
4. A printing apparatus for depositing ink droplets on a surface of a medium to form an image, the printing apparatus comprising:
a medium-conveying part; nozzles; a light-irradiation part; a medium-deforming part; and a controller configured to control the parts,
the medium-conveying part being configured to convey the medium so that the medium supplied from an upstream side is released on a downstream side,
the nozzles being configured to discharge ink droplets curable by light irradiation onto the medium,
the light-irradiation part being configured to irradiate the medium with light,
the medium-deforming part being arranged on the upstream side of the nozzles, and being configured to hold the medium from the front and back and deform the medium so that an irregular shape is formed in cross section, the medium-deforming part including a first roller and a second roller facing the first roller in a first direction, the first roller having at least one projecting part projecting outward from an outer circumference of the first roller and extending along a second direction perpendicular to the first direction and the conveying direction of the medium, the at least one projecting part extending straight along the second direction,
the controller being configured to perform a medium-deforming step, an image-forming step, and a light-irradiating step,
in the medium-deforming step, the medium being conveyed downstream by the medium-conveying part after the medium is deformed by the medium-deforming part,
in the image-forming step, the ink droplets being discharged by the nozzles to form an image on the surface of the medium, and
in the light-irradiating step, the ink droplets discharged onto the medium being irradiated with light by the light-irradiation part to cure the droplets,
the controller being further configured to control the at least one projecting part to be pressed against the medium while the first roller and the second roller hold the medium therebetween in the medium-deforming step.
2. The printing apparatus according to
the light-irradiation part arranged downstream of a head part further includes a temporary-curing irradiation part on the upstream side, and a permanent-curing irradiation part on the downstream side,
the controller performs a temporary curing step and a permanent curing step,
the temporary-curing irradiation part irradiates light for preventing the flow of the ink droplets,
the permanent-curing irradiation part irradiates light having higher energy in comparison with the light irradiated by the temporary-curing irradiation part,
in the temporary curing step, the ink droplets deposited on the medium by the nozzles are irradiated with light by the temporary-curing irradiation part, and
in the permanent curing step, the ink droplets irradiated with light in the temporary curing step are irradiated with light, cured, and fixed to the medium.
3. The printing apparatus according to
6. The printing method according to
the deforming of the medium being performed after the feeding of the medium.
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This application claims priority to Japanese Patent Application No. 2011-064384 filed on Mar. 23, 2011. The entire disclosure of Japanese Patent Application No. 2011-064384 is hereby incorporated herein by reference.
1. Technical Field
The present invention relates to a printing apparatus in which ink cured by irradiation with light is used. The invention also relates to a method for preventing uneven gloss on an image printed using the printing apparatus.
2. Background Technology
Inkjet printers for discharging ink onto a medium to form an image belong to the class of printing apparatuses. In such of these inject printers, images are printed using light-curable ink that is irradiated with ultraviolet light or other light and cured (for example, refer to Patent Citation 1). In inkjet printers that use such light-curable ink, the occurrence of bleeding (running) caused by combinations of ink droplets can be suppressed by curing the ink droplets discharged on the medium with light.
Japanese Patent Registration No. 4321050 (Patent Citation 1) is an example of the related art.
In inkjet printers in which light-curable ink is used, a problem arises in which unevenness in gloss level occurs in correspondence with the amount of ink per unit area on the medium. For example, the gloss level is low in sections in which the amount of ink is sparse, such as those displaying the color of skin or the like. Conversely, the amount of ink is considerable and the gloss level is high in solidly filled sections such as those of a pupil or the like. Therefore, in a case in which a human face is the printed image, the gloss levels vary according to the position on the face, resulting in an unnatural image.
An advantage of the invention is to provide a printing apparatus capable of printing an image having even gloss levels even when the amount of ink is unevenly distributed on the medium. Additional advantages will be described below.
The primary invention, which was devised to achieve the aforementioned advantage, provides a printing apparatus for depositing ink droplets on a surface of a medium to form an image;
the printing apparatus including:
including a medium-conveying part, nozzles, a light-irradiation part, a medium-deforming part, and a controller for controlling the parts;
the medium-conveying part conveying the medium so that the medium supplied from an upstream side is released on a downstream side;
the nozzles discharging ink droplets curable by light irradiation onto the medium;
the light-irradiation part irradiating the medium with light;
the medium-deforming part being arranged on the downstream side of the nozzles, holding the medium from the front and back, and deforming the medium so that an irregular shape is formed in cross section;
the controller performing a medium-deforming step, an image-forming step, and a light-irradiating step;
in the medium-deforming step, the medium being conveyed downstream by the medium-conveying part after the medium is deformed by the medium-deforming part;
in the image-forming step, the ink droplets being discharged by the nozzles to form an image on the surface of the medium; and
in the light-irradiating step, the ink droplets discharged onto the medium being irradiated with light by the light-irradiation part to cure the droplets.
Other characteristics of the invention are made apparent from the descriptions of the specification and the attached drawings.
Referring now to the attached drawings which form a part of this original disclosure:
The gloss level of a printed image is dependent on the state of the light reflected from a medium struck by natural light. For example, the gloss level is low when the reflected light is diffused; this state is referred to as “matte.” Conversely, a high gloss level can be obtained when the light approaches specular reflection; this state is referred to as “glossy.” Unevenness in the gloss level of printed images occurs in inkjet printers in which light-curable ink is used, as described above. In general terms, gloss level is dependent on the amount of ink per unit area on the medium, that is, on the amount of ink droplets (ink drops) sprayed onto the medium.
In contrast, the pupil or other dark-colored section is expressed by entirely filling the image area, as shown in
The aforementioned is a summary of causes of uneven gloss. However, the mechanism for producing uneven gloss schematically shown in
As described above, uneven gloss occurs due to the density of the ink drops on the medium in a printer in which light-curable ink is used. Moreover, the density of ink drops and the gloss level are not in a simple proportional relationship, making it impossible for the uneven gloss on the same medium to be eliminated by simply making the gloss level uniform over the entire image by using glossy paper, matte paper, or another surface-treated medium. Reforming the ink is a consideration, but the physical properties related to the gloss level of the ink must be optimized without losing the original characteristic of the light-curable ink, that is, the ability to suppress bleeding. Furthermore, the ink discharge method and the like suitable to the physical properties of the ink must also be optimized. The development and research of ink, discharge control, and other peripheral technologies therefore require extensive time and cost to develop. In view of this, a goal was set to achieve a uniform gloss level in matte, that is, to change the technical thinking, by physically modifying the cross-sectional shape of the medium rather than by reforming the ink or surface-treating the medium.
The printing apparatus according to this embodiment can be provided with the below-described characteristics in addition to the characteristics provided by an embodiment corresponding to the primary aspect of the invention.
The medium-deforming part is configured from rollers for holding the medium while being orthogonal to the conveying direction of the medium, and irregularities are formed on the surface of one of the rollers. In this case, the surface of the medium on which the ink droplets are deposited is the front surface, the roller provided with irregularities is arranged facing the rear surface of the medium, and the roller provided with an elastic surface and formed from a material lacking any irregularities is arranged facing the front surface.
In addition, the printing apparatus is provided, wherein:
the light-irradiation part arranged downstream of a head part further includes a temporary-curing irradiation part on the upstream side, and a permanent-curing irradiation part on the downstream side;
the controller performs a temporary curing step and a permanent curing step;
the temporary-curing irradiation part irradiates light for preventing the flow of the ink droplets;
the permanent-curing irradiation part irradiates light having higher energy in comparison with the light irradiated by the temporary-curing irradiation part;
in the temporary curing step, the ink droplets deposited on the medium by the nozzles are irradiated with light by the temporary-curing irradiation part; and
in the permanent curing step, the ink droplets irradiated with light in the temporary curing step are irradiated with light, cured, and fixed to the medium.
An example of the invention further provides a printing method using a printing apparatus in which light-curable ink is discharged as droplets from nozzles and deposited on a medium, the deposited droplets are irradiated with light and cured, and an image composed of minute dots is formed on the medium; the printing method wherein the printing apparatus performs a step for deforming the medium so that an irregular shape is formed in cross section before the image-forming step is performed.
Basic Configuration and Operation of Printer
An inkjet printer (hereinafter referred to as a “UV printer”) of a type in which UV ink is cured by ultraviolet irradiation is given as a more specific embodiment of the invention. The overall configuration of the UV printer 1 according to this embodiment is shown in
A controller 10 is a control unit for controlling the UV printer 1. The controller includes a CPU 11 as a processor-controller, a memory 12 having a storage area for a program performed by the CPU 11 and an operating area for the program, a unit controller 13 for controlling the operation of individual units (20 to 60), an interface (IF) 14 for transmitting data between a computer 100, which is an external device, and the CPU 11, and the like.
A conveying unit 20 includes a mechanism or circuit for conveying paper or another medium S in a designated direction. In this example, the rearward direction of the UV printer 1 is upstream, the frontward direction is downstream, and the medium S is conveyed so as to be supplied from the upstream side and released from the downstream side.
A detector group 50 includes sensors for detecting the various states inside of the UV printer 1, each of the sensors included in the detector group 50 outputs the detection results (detection data) to the controller 10, and the controller 10 performs feedback control on each of the units on the basis of the detection data. The detector group 50 can, for example, include a rotary encoder for detecting the rotations of the conveying roller 22, and other sensors.
A head unit 30 is adapted to discharge ink toward the medium S, and is configured so as to include, in addition to a nozzled head 31, ink tanks, a pump for supplying ink to the head 31 from the ink tanks, and the like. The UV printer 1 shown here is a line printer arranged so that the head 31 provided with ink-discharging nozzles on the lower surface 32 thereof extends in the widthwise direction (hereinafter referred to as the “line direction”) orthogonal to the conveying direction of the medium S. Multicolored ink for multicolor printing is loaded into individual ink tanks. An example of the nozzle arrangement of the head 31 is shown in
Each of the nozzles N is provided with an ink chamber (not shown) and a piezo element. Ink drops are discharged from the nozzles N when the ink chambers are expanded and contracted by the driving of the piezo elements. An image in which dots made of ink drops are arranged in two dimensions on the medium S is formed on the medium S when the head 31 intermittently discharges ink drops during conveyance of the medium S by the control of the controller 10.
A UV irradiation unit 40 includes a metal-halide lamp or other UV light source for irradiating ultraviolet light to cure UV ink, and a drive circuit or the like for lighting the UV light source. A UV light source 41 is provided so as to be arranged on the downstream side in the conveying direction in relation to the head 31 and to extend in the line direction. The irradiation range of ultraviolet light is an area longer than the width of the medium S, which is the print target. The UV irradiation unit 40 causes the UV light source 41 to light up toward the medium S when the medium S is moved in the conveying direction by the control of the controller 10. The UV ink drops on the medium S are thereby cured.
Function for Preventing Uneven Gloss
As described above, uneven gloss is produced in UV printers due to the amount of ink per unit area on the medium. The UV printer 1 according to the present embodiment is provided with a medium-deforming unit 60 as a configuration bearing the function for preventing uneven gloss. The operation of the function for preventing uneven gloss in the UV printer 1 of this embodiment is described hereinafter as an example of the invention.
As shown in
The ink I is discharged toward the upper surface (front surface) Ss of the deformed medium S, and the ink drops d1 are deposited on the medium S (D). The ink drops d1 on the medium S are then irradiated with ultraviolet light L and cured, and the medium S is ultimately released.
A metal roller provided with irregularities on the surface by machining can be used as the medium-deforming roller 61; a plastic molded article can also be used. In the present example, a metal roller is used in which the surface of the roller is etched and minute irregularities are formed in the surface of the roller in order to make the irregular shape of the medium less structured.
The driven roller 62 for holding the medium S together with the medium-deforming roller 61 can be a roller similar to the medium-deforming roller 61, but is more preferably a roller in which the surface of the metal roller is coated with, for example, a flexible material such as silicone rubber so as to be able to press down on the medium S while following the irregular shape of the medium-deforming roller 61. It is apparent that irregularities can also be present on the flexible surface of the driven roller.
The medium-deforming roller 61 can be arranged against the medium S on the front surface Ss or the rear surface Sb, but a case is considered in the present example in which a surface treatment (gloss treatment, matte treatment, or the like) is performed on the front surface Ss of the medium S on which ink drops “d” are deposited to form an image, and the driven roller 62 is arranged on the front surface Ss of the medium S. Conditions are thereby created in which the front surface Ss of the medium S on which an image is formed is directly pressed by the medium-deforming roller 61, and the coating or the like formed by the surface treatment is not damaged. As long as the actual depth of the irregularities on the medium S is about the size (diameter) of the ink drops “d”, the ink drops form a film shape on a solidly printed or otherwise highly glossy area. Even when this happens, the surface of the film becomes irregularly shaped, the gloss level decreases, and a matte appearance is obtained. In the present example, the size of the ink drops “d” is about 1 μm, and the depth of the irregularities provided to the medium S is also about 1 μm. It is apparent that the depth and pitch of the irregularities formed on the medium S are set in a suitable manner in correspondence with the viscosity that contributes to the size and shape of the ink drops “d,” and other characteristics of the ink drops and ink.
Among printers that use light-curable ink, there are types that perform “temporary curing,” that is, perform a process in which ink drops are irradiated with low-energy light immediately after deposition to cure the surface of the ink drops in order to prevent the flow of ink until the ink drops deposited on the medium are fixed by high-energy light irradiation. Temporary curing is very effective for the purpose of preventing bleeding, but the uneven gloss described above can become more pronounced.
Specifically, the ink drops d1 deposited on the medium S in the UV printer 1 of this embodiment are irradiated with high-energy ultraviolet light, hardened, and fixed to the medium S, as shown in
Conversely, in temporary-curing printers, stronger light diffusion occurs in areas having low ink-drop density because the ink drops on the medium preserve the shape obtained immediately after deposition. Accordingly, deforming the medium so as to have an irregular shape in cross-section allows even greater effectiveness in preventing uneven gloss to be obtained in temporary-curing printers.
The UV printer 1 according to this embodiment is a line printer, but can be a serial printer. Specifically, a serial printer can have a configuration in which the head moves in a direction intersecting with the conveying direction, rather than a configuration in which the head is arranged in the line direction across the width of the medium.
In the UV printer 1 according to this embodiment, an example is given of a piezo inkjet printer in which voltage is applied to a driving element (piezo element) to spray fluid by causing the expansion and contraction of an ink chamber, but the method for discharging fluid is not limited to this example, and a thermal inkjet printer can also be used in which bubbles are formed in the nozzles using a heater element, and liquid is sprayed by the bubbles.
In addition, in each of the printers according to the various embodiments of the invention, beginning with the UV printer 1 according to this embodiment, the medium is not limited to paper, and a plastic film or another medium having any form can be a print target as long as the irregular shapes applied prior to printing are maintained. It is apparent that the medium can be of a continuously conveyed form such as rolled paper, and can be of an individually conveyed form such as a single sheet of paper.
The conveying direction of the medium is such that the side on which the medium is supplied is the upstream side, and the side on which the medium is released is the downstream side, but the conveying direction is not limited to a unidirectional configuration from upstream to downstream. As shown, for example, in
The invention can be applied to inkjet printers for forming images using light-curable ink on, for example, media (OHP sheet, coated paper, and the like) that usually has low ink penetration.
Takahashi, Toru, Wada, Hiroshi, Kondo, Takamitsu, Tanase, Kazuyoshi
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
7152970, | Mar 12 2003 | Konica Minolta Holdings, Inc. | Image forming apparatus having a plurality of printing heads |
20060284953, | |||
20090244175, | |||
JP2004042548, | |||
JP4321050, |
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